Electronic element with a shielding

ABSTRACT

Element comprising a carrier ( 1 ) having at least an electrically conductive mass plane ( 2 ); a flipped chip die ( 5 ) mounted on said carrier ( 1 ), the flipped chip die having a backside ( 5 A) opposite to a front side ( 5 B) directed towards the carrier ( 1 ); and an electromagnetic interference shield which comprises an electrically conductive means ( 8 ) electrically connecting an electrically conductive layer ( 7 ) of the backside ( 5 A) of the flipped chip die ( 5 ) to the mass plane ( 2 ) of the carrier ( 1 ).

[0001] The invention relates to an electronic element comprising:

[0002] a carrier having an electrically conductive mass plane;

[0003] a flipped chip die mounted on said carrier, said flipped chip die having a backside opposite to a front side directed towards the carrier; and

[0004] an electromagnetic interference shield electrically connected to the mass plane of the carrier.

[0005] Electromagnetic interference (EMI) problems are well known. EMI is a particular problem in cellular phones in which an antenna emits radio frequencies (RF) which could affect the other circuitry operating in the phone.

[0006] For solving this problem, it has been proposed to use EMI shielding.

[0007] U.S. Pat. No. 6,092,281, the content of which is incorporated in the present specification by reference, teaches such an EMI shielding.

[0008] In the shielding of U.S. Pat. No. 6,092,281, the carrier is provided with electrically conductive dams forming a chamber or pocket , the bottom of which is a portion of the carrier. In said chamber, the flipped chip is placed. The chamber or pocket is closed with an electrically conductive cover distant from the flipped chip. The free space between the flip chip and the dams and cover is filled with an electrically insulating encapsulating material.

[0009] The production of such shielding is expensive, as it requires separate shielding cover, formation of dams, soldering operation, filling operation with insulating encapsulating material, etc.

[0010] The invention seeks to provide an electronic element, which provides shielding without requiring the use of dams or a cover to be soldered to dams.

[0011] In accordance with the invention, this object is accomplished in an element of the type disclosed in the first paragraph of the present specification, in that the electromagnetic interference shield comprises an electrically conductive means electrically connecting an electrically conductive layer on the backside of the flipped chip die, preferably covering the whole backside of the flipped chip die, to the mass plane of the carrier.

[0012] Advantageously, the conductive means electrically connects the conductive layer on the backside of the flipped chip die to the mass plane of the carrier, so as to make a faraday cage around the die.

[0013] Preferably, the electrically conductive means electrically connecting the conductive layer on the backside of the flipped chip die to the mass plane of the carrier comprises conductive glue and/or a conductive tape.

[0014] According to another embodiment, the electrically conductive connection means, connecting the conductive layer on the backside of the flipped chip die to the mass plane of the carrier, comprises a conductive connection through the die, connecting the conductive layer to bond pads on the front side of the die that is connected to the carrier.

[0015] The invention further relates to an apparatus comprising an electronic circuit comprising at least an element of the invention.

[0016] Preferably, it comprises at least an antenna for emitting a radio frequency. The apparatus of the invention is for example an apparatus for GSM and DECT applications.

[0017] Details and characteristics of the invention will appear from the following description in which reference is made to the attached drawings, wherein:

[0018]FIG. 1 is a partial perspective view of an electronic element of the invention, partially cut away and with a covering mold component in interrupted line;

[0019]FIG. 2 is a cross-section of the electronic element of FIG. 1;

[0020]FIG. 3 is a cross-section similar to the one of FIG. 2, but pertaining to another form of embodiment of the invention.

[0021] The electronic element shown in FIGS. 1 and 2 comprises a carrier 1 having at least an electrically conductive mass plane 2 consisting of a layer 2A connected to a mass 3.

[0022] The carrier 1 is advantageously of the type comprising, in addition to the mass plane 2, several conductive layers or intermediate layers for the various connections to be carried out.

[0023] A flipped chip die 5 is mounted on said carrier 1 with interposition of a bump layer 6 for the mechanical and electrical connection of the die 5 with the carrier 1.

[0024] Said flipped chip die has a backside 5A opposite to a front side 5B directed towards the carrier, said backside 5A being covered with a top electrically conductive layer 7.

[0025] Said layer 7 covers preferably the complete backside 5A and is for example a metallic layer or layer containing conductive material, such as gold, silver, carbon black, fibers, sheet, filaments, lattices, etc., possibly mixed in a resin layer.

[0026] An electrically conductive connection means 8 forms an electrical connection between the layer 7 and the electrically conductive mass plane 2 of the carrier 1.

[0027] In the embodiment shown in FIGS. 1 and 2, the conductive connection means 8 is a conductive glue which adheres, on the one hand, to all sides edges of the layer 7 and, on the other hand, to the layer 2A connected to the mass 3.

[0028] An under-fill 9 made of not conductive material is placed between the bumps 6A of the bump layer 6 which is used for mechanical contact.

[0029] A mold component 10 in insulating material, for example in plastic, covers the layer 7 and the connection means 8 for protection.

[0030] A faraday cage is thus built around the die 5 by the conductive layer 7 covering the backside 5A of the die 5, the conductive connection means 8 and the mass plane 2 or the layer 2A of the carrier 1 connected to the mass 3.

[0031] In a not shown embodiment, the conductive glue covers the layer 7 completely and forms therefore a further protection for the die 5.

[0032] In a further embodiment, the layer 7 is also formed by the same conductive glue as the connection means 8 and in one piece with these means.

[0033] The connection means 8 may be a conductive tape instead of a conductive glue.

[0034]FIG. 3 shows such embodiment wherein a conductive tape, forming the connection means 8, is applied on the side edges of the layer 7.

[0035] In alternative embodiments, the tape covers also the layer 7 or the layer 7 is a portion of the tape which covers also the backside 5A of the die 5.

[0036] In another alternative embodiment, the connection means 8 may comprise a conductive connection extending through the silicon material of the die 5.

[0037] This connection connects the conductive layer 7 covering the backside 5A to bond pads at the side of the die 5 that is connected to the electrically conductive portion 2 of the carrier 1.

[0038] This connection may be incorporated during the manufacturing of the die 5.

[0039] In all forms of embodiment, the electronic element of the invention can be manufactured easily and at a low cost, as no soldering or bonding wires are required.

[0040] The element of the invention finds many application in apparatuses where EMI (RF, EMC, etc.) have to be prevented, for example in apparatuses comprising emitting means, emitting antenna, etc., such as GSM and DECT. 

1. Electronic element comprising: a carrier (1) having at least an electrically conductive mass plane (2); a flipped chip die (5) mounted on said carrier (1), said flipped chip die having a backside (5A) opposite to a front side (5B) directed towards the carrier (1) ; and an electromagnetic interference shield electrically connected to the mass plane (2) of the carrier (1), characterized in that the electromagnetic interference shield (7-8) comprises an electrically conductive connection means (8) electrically connecting an electrically conductive layer (7) on the backside (5A) of the flipped chip die (5) to the mass plane (2) of the carrier (1).
 2. Element according to claim 1, characterized in that the electrically conductive connection means (8) electrically connects the conductive layer (7) of the backside (5A) of the flipped chip die (5) to the mass plane (2) of the carrier (1), so as to make a whole faraday cage around the die (5).
 3. Element according to claim 2, characterized in that the electrically conductive connection means (8) electrically connecting the conductive layer (7) of the backside (5A) of the flipped chip die (5) to the mass plane (2) of the carrier (1) comprises conductive glue.
 4. Element according to claim 2, characterized in that the conductive connection means (8) electrically connecting the conductive layer (7) of the backside (5A) of the flipped chip die (5) to the mass plane (2) of the carrier (1) comprises conductive tape.
 5. Element according to claim 1, characterized in that the connection means (8) also cover the conductive layer (7) on the backside (5A).
 6. Element according to claim 1, characterized in that the connection means (8) and the conductive layer (7) covering the backside (5A) of the die (5), are of the same material and form one whole.
 7. Element according to claim 1, characterized in that the conductive layer (7) covers completely the backside (5A) of the die (5).
 8. Element according to claim 1, characterized in that the electrically conductive connection means (8) connecting the conductive layer (7) on the backside (5A) of the flipped chip die (5) to the mass plane (2) of the carrier (1) comprises a conductive connection through the die (5), connecting the conductive layer (7) to bond pads on the front side (5B) of the die (5) that is connected to the carrier.
 9. Apparatus comprising an electronic circuit comprising at least an electronic element according to any of the claims 3, 4 or 8, and further to at least an antenna for emitting or receiving a radio frequency signal. 